Regien G. Schoemaker

Renin-Angiotensin System Components in the Interstitial Fluid of the Isolated Perfused Rat Heart: Local Production of Angiotensin I

We used a modification of the isolated perfused rat heart, in which coronary effluent and interstitial transudate were separately collected, to investigate the uptake and clearance of exogenous renin, angiotensinogen, and angiotensin I (Ang I) as well as the cardiac production of Ang I. The levels of these compounds in interstitial transudate were considered to be representative of the levels in the cardiac interstitial fluid. During perfusion with renin or angiotensinogen, the steady-state levels (mean +/- SD) in interstitial transudate were 64 +/- 34% (P < .05 for difference from the arterial level, n = 8) and 108 +/- 42% (n = 6) of the arterial level, respectively; the levels in coronary effluent were not significantly different from those in interstitial transudate. Ang I was not detectable in interstitial transudate during perfusion with Tyrodes buffer or angiotensinogen. It was very low in interstitial transudate during perfusion with renin and rose to much higher levels during combined renin and angiotensinogen perfusion. The total production rate of Ang I present in interstitial fluid could be largely explained by the renin-angiotensinogen reaction in the fluid phase of the interstitial compartment. In contrast, the total production rate of Ang I present in coronary effluent and the net ejection rate of Ang I via coronary effluent were, respectively, 4.6 +/- 2.2 and 2.8 +/- 1.3 (P < .01 and P < .05 for difference from 1.0, n = 6) times higher than could be explained by Ang I formation in the fluid phase of the intravascular compartment. Ang I from the interstitial fluid contributed little to the Ang I in the intravascular fluid and vice versa. These data reveal two tissue sites of Ang I production, ie, the interstitial fluid and a site closer to the blood compartment, possibly vascular surface-bound renin. There was no evidence that the release of locally produced Ang I into coronary effluent and interstitial transudate occurred independently of blood-derived renin or angiotensinogen.

Determinants of coronary reserve in rats subjected to coronary artery ligation or aortic banding

OBJECTIVE We investigated whether decreased coronary reserve in hearts after coronary artery ligation or in hearts from rats after aortic banding can be related to remodeling of resistance arteries. METHODS Maximal coronary flow (absolute flow) and cardiac perfusion (flow corrected for heart weight) were determined in isolated, perfused rat hearts after adenosine or nitroprusside, at 3 and 8 weeks after coronary artery ligation or 4-5 weeks after aortic banding. Perivascular collagen and medial thickness of resistance arteries were determined by morphometry. RESULTS maximal coronary flow of infarcted hearts had been restored to sham values at 3 weeks. Growth of cardiac muscle mass from 3 to 8 weeks exceeded the increase in maximal coronary flow, leading to a decreased perfusion at 8 weeks. A slight, transient increase in perivascular collagen, but no medial hypertrophy, was found after infarction. After aortic banding perivascular fibrosis and medial hypertrophy led to a decreased maximal coronary flow in both the hypertrophied left and the non-hypertrophied right ventricle. Consequently, perfusion of the left ventricle was most severely reduced. CONCLUSIONS Reduced maximal perfusion after aortic banding is determined by both cardiac hypertrophy and vascular remodeling. In contrast, during infarction-induced remodeling, reduction of perfusion is not determined by vascular remodeling, but mainly by disproportional cardiac hypertrophy relative to vascular growth.

Hypothermia extends the cardioprotection by ischaemic preconditioning to coronary artery occlusions of longer duration

OBJECTIVE To test the hypothesis that mild hypothermia potentiates the cardioprotection afforded by ischaemic preconditioning so that infarct size limitation can be obtained after coronary artery occlusion (CAO) durations which exceed the cardioprotective range (> 90 min) of either hypothermia or ischaemic preconditioning alone. METHODS Four groups of anaesthetized rats were subjected to different durations of CAO: (i) normothermia (N, 36.5-37.5 degrees C, n = 29), (ii) normothermia + ischaemic preconditioning (N + IP, 15 min CAO followed by 10 min of reperfusion, n = 35), (iii) hypothermia (H, 30-31 degrees C, n = 31) and (iv) hypothermia + ischaemic preconditioning (H + IP, n = 24). Infarct size (IA/AR) was determined after 3 hours of reperfusion using trypan blue to delineate the area at risk (AR) from non-risk region and nitroblue tetrazolium to delineate infarcted area (IA) from viable myocardium. RESULTS In N the CAO duration versus infarct size relation had a sigmoid shape with virtually no infarction occurring at 15 min CAO and 56 +/- 5% of the area at risk being infarcted at 30 min CAO reaching a plateau of 71 +/- 2% at 60 min CAO. Hypothermia produced a rightward shift of the relation resulting in an approximately 15 min delay in onset of infarction. Ischaemic preconditioning produced a similar reduction in infarct size (23 +/- 4%) at 30 min CAO compared to hypothermia (13 +/- 3%) but also limited infarct size at 45 min to 36 +/- 3% and at 60 min CAO to 50 +/- 3% suggesting a slowing of infarct progression. Neither intervention limited IA/AR produced by 120 min CAO. In H + IP, combined hypothermia and ischaemic preconditioning resulted in synergistic infarct size reduction so that at 45 min and 60 min CAO IA/AR was reduced to 17 +/- 3% and 23 +/- 3%, respectively, and even at 120 min CAO to 58 +/- 5%, which was significantly smaller than during normothermic control conditions (p < 0.05 vs. N). CONCLUSION Mild hypothermia limited IA/AR modestly but markedly enhanced the cardioprotection afforded by ischaemic preconditioning in the in situ rat heart so that irreversible damage produced by even prolonged coronary artery occlusions was limited.

5-Hydroxytryptamine stimulates human isolated atrium but not ventricle

Although 5-hydroxytryptamine (5-HT) elicits positive inotropic effects in the human isolated atrium via 5-HT4 receptors, no data are available about its effects in the ventricular myocardium. We investigated the inotropic effects of 5-HT in human healthy ventricular trabeculae and compared these effects with those in right atrial trabeculae. Baseline force of contraction as well as the response to noradrenaline, used to check inotropic responsiveness of the tissue, was significantly higher in ventricular (391 +/- 10 and 719 +/- 126 mg, respectively) than in atrial tissue (189 +/- 5 and 383 +/- 79 mg, respectively). However, 5-HT increased the force of contraction up to 309 +/- 82 mg at 10(-4) M in atrial trabeculae, but failed to affect the force of contraction in ventricular tissue. We conclude that, in contrast to atrial tissue, 5-HT is ineffective as a positive inotropic agent in human ventricular trabeculae. This finding obviously rules out the development of 5-HT4 receptor agonists for the treatment of heart failure, but suggests the absence of ventricular side-effects of 5-HT4 receptor (ant)agonists should these agents be used in the treatment of gastrointestinal disorders.

Cardioprotection by ischemic and nonischemic myocardial stress and ischemia in remote organs. Implications for the concept of ischemic preconditioning.

Ischemic preconditioning studies employ one or more brief total coronary artery occlusions separated by complete reperfusion to limit infarct size during a subsequent prolonged coronary artery occlusion. We now present evidence that in anesthetized pigs a partial coronary artery occlusion without intervening reperfusion between the partial and prolonged total occlusions can also precondition the myocardium provided that the reduction in coronary blood flow is sufficiently severe. Thus infarct size was reduced after a 60 min total coronary artery occlusion when the total occlusion was preceded by a partial coronary occlusion that reduced coronary blood flow by 70% but not when the flow reduction was only 30%. In this two-stage coronary occlusion model the degree of protection appears greater in the epicardial than in the endocardial half. In view of evidence that brief occlusions of a coronary artery also protect myocardium outside its perfusion territory, we subsequently investigated whether ischemia in remote organs can protect myocardium. Because of reports that development of infarct size may be temperature dependent, we also investigated whether the cardioprotection by remote organ ischemia was temperature dependent. In anesthetized rats a 15 min coronary artery occlusion was more effective in reducing infarct size produced by a subsequent 60 min total coronary artery occlusion when the experiments were performed at a body core temperature of 30-31 degrees C than at 36-37 degrees C, while infarct size of animals which were subjected to only the 60 min total coronary artery occlusion was the same for the two body core temperatures. In rats with a body core temperature of 36-37 degrees C a 15 min mesenteric artery occlusion, but not a 15 min renal artery occlusion, reduced infarct size produced by a subsequent 60 min coronary artery occlusion. When the experiments were performed at 30-31 degrees C both the mesenteric and renal artery occlusions were protective. These observations indicate the local myocardial ischemia is not required to protect the myocardium during a prolonged coronary occlusion. We further investigated whether myocardium could also be protected by a cardiac stimulus which does not produce ischemia at all. For this purpose we electrically paced the left ventricle of anesthetized pigs to produce heart rates of 200 bpm (which did not lead to ischemia as assessed by a number of functional and biochemical variables) and found that 30 min of ventricular pacing reduced myocardial infarct size produced by a subsequent 60 min coronary artery occlusion. The protection by ventricular pacing involved activation of K+ATP channels as pretreatment with glibenclamide abolished the protection by ventricular pacing. We conclude that a number of distinctly different stimuli can protect the myocardium suggesting that ischemic myocardial preconditioning could be just one feature of a more general protection phenomenon.

Behavioral changes following chronic myocardial infarction in rats

Myocardial infarction evokes major physiological changes because of the acute loss of functional cardiac tissue, resulting in more or less severe symptoms of congestive heart failure. In addition, general well-being of patients, their quality of life, is reduced. This includes anxiety/depression, loss of interest in environment and social interactions, sexual problems, and sleep disturbances. Postinfarction treatment is aimed mainly at improving life expectancy, whereas less attention is paid to the quality of that life. The aim of the present study was to determine behavioral changes after myocardial infarction in a (otherwise proven as clinically relevant) rat model for heart failure after myocardial infarction. We have chosen for behavioral tests based upon certain aspects of quality of life in patients. Anxiety/depression, interest in environment, and mobility, tested in an open field, revealed that infarcted rats are more anxious (as inferred from a higher preference for the safe corner area and less visits to the middle area), have less interest in a new environment [as indicated by less exploratory behavior and a longer time before they go into the new area (free exploration)], and showed less mobility (as indicated by reduced distance walked and less time spent on walking). In a test on social interaction, infarcted rats spent less time on social behavior and displayed even somewhat more walking away, suggesting active avoidance of social interaction. The observed behavioral changes in infarcted rats match very well with the aspects of reduced quality of life in postinfarct patients.(ABSTRACT TRUNCATED AT 250 WORDS)

Altered cardiac collagen and associated changes in diastolic function of infarcted rat hearts

OBJECTIVE Anti-inflammatory drugs have been shown to modulate collagen deposition during myocardial infarction (MI) induced remodeling. Chronic effects of methylprednisolone (5 mg/kg/day) and low-dose aspirin (25 mg/kg/day) on cardiac collagen and left ventricular diastolic function were studied in rat hearts, 21 days after MI. METHODS Left ventricular function was assessed at baseline and after beta-adrenergic stimulation with isoproterenol in isolated perfused hearts, using an intraventricular balloon. After diastolic arrest, left ventricular pressure-volume curves were obtained. Left ventricular dilation was defined as the corresponding left ventricular volume at 20 mmHg left ventricular diastolic pressure. In histological sections, perivascular and interstitial collagen content were quantified morphometrically as the Sirius Red positive area in the non-infarcted interventricular septum. RESULTS Impaired baseline left ventricular function of MI-hearts was improved by methylprednisolone but not by low-dose aspirin. Isoprotenerol significantly enhanced systolic function in all hearts, whereas it augmented the decrease in left ventricular diastolic pressure only in methylprednisolone-treated MI-hearts. The rightward shift of the pressure-volume curve after MI was aggravated by methylprednisolone but not with low-dose aspirin treatment. Low-dose aspirin reduced perivascular but not interstitial collagen whereas methylprednisolone decreased both perivascular and interstitial collagen. CONCLUSIONS Our findings indicate that MI-induced collagen deposition in the spared myocardium can be affected by chronic therapy with low-dose aspirin or methylprednisolone. The effects on interstitial collagen seemed reflected in an altered left ventricular diastolic function.

Characterization of the positive and negative inotropic effects of acetylcholine in the human myocardium

In the human isolated myocardium, acetylcholine (10(-9) to 10(-3) M) elicited a biphasic inotropic effect (a decrease in the lower and an increase in the higher concentration range) in atrial and a positive inotropic effect in ventricular trabeculae. However, under conditions of raised contractility achieved by exposure to noradrenaline (10(-5) M), only negative inotropic effects were observed in both atria and ventricles. Atropine (10(-6) M), but not propranolol (10(-6) M), antagonized both positive and negative inotropic effects of acetylcholine, thus showing that the responses were mediated by muscarinic acetylcholine receptors. The use of subtype selective muscarinic receptor antagonists (10(-7) to 10(-5) M), pirenzepine (M1 > M3 > M2), AF-DX 116 (11-([2-[(diethylamino)-methyl]-1-piperidyl]acetyl)-5,11-dihydro-6H- pyridol[2,3-b][1,4]benzodiazepine-6-one base; M2 > M1 > M3) and HHSiD (p-fluorohexahydro-siladifenidol hydrochloride; M3 > or = M1 >> M2) revealed that the negative inotropic effect of acetylcholine in atrial as well as the positive inotropic effect in ventricular trabeculae were best antagonized by AF-DX 116 and not by pirenzepine, suggesting the involvement of the muscarinic M2 receptor subtype, possibly linked to different second messenger systems. On the other hand, the positive inotropic effect of acetylcholine (10(-6) to 10(-3) M) in the atrial tissue, observed only in preparation with depressed contractility, was not effectively antagonized by either AF-DX 116 or HHSiD, but was significantly reduced by pirenzepine. (ABSTRACT TRUNCATED AT 250 WORDS)

Different pharmacological responses of atrium and ventricle: Studies with human cardiac tissue

It has been recently reported that 5-hydroxytryptamine (5-HT) increases force of contraction in atrial tissue but not in ventricular tissue. In the present study with trabeculae obtained from non-diseased human hearts, we investigated whether this difference in the contractile responses is specific for 5-HT or is also observed for other substances: calcitonin gene-related peptide (CGRP), angiotensin II, adenosine, somatostatin and acetylcholine. CGRP (10(-9) to 10(-7) M) and angiotensin II (10(-9) to 10(-5) M) caused concentration-dependent increases in force of contraction in atrial trabeculae (up to 36 +/- 8% and 42 +/- 8% of the response to 10(-5) M noradrenaline, respectively). Similar to 5-HT, no effects were observed with CGRP and angiotensin II in ventricular trabeculae. Adenosine (10(-8) to 10(-5) M) and somatostatin (10(-8) to 10(-6) M) caused concentration-dependent negative inotropic effects on baseline atrial contractility (-54 +/- 17% and -51 +/- 25%, respectively), but no response was found on baseline ventricular contractility. Adenosine, but not somatostatin, reduced force of contraction after pre-stimulation with 10(-5) M noradrenaline in atrial tissue and, to a lesser extent, in ventricular tissue. Acetylcholine exhibited a biphasic concentration-response curve in the atrial tissue, consisting of an initial negative inotropic response (10(-9) to 10(-7) M, from 120 +/- 41 mg at baseline to 48 +/- 16 mg at 10(-7) M), followed by a positive inotropic response (10(-6) to 10(-3) M, from 48 +/- 16 mg at 10(-7) M to 77 +/- 15 mg).(ABSTRACT TRUNCATED AT 250 WORDS)

5-Hydroxytryptamine increases contractile force in porcine right atrium but not in left ventricle

SummaryPositive chronotropic as well as inotropic effects of 5-hydroxytryptamine (5-HT) have been observed in pig artial tissue, but no data are available about the direct effects of 5-HT on ventricular tissue. In the present study we investigated inotropic effects of 5-HT on atrial and ventricular trabeculae obtained from hearts of 3 months old pigs. The baseline isometric contractile force was significantly higher in ventricular (4.14±1.25 mN) than in atrial tissue (0.47±0.11 mN). A noradrenaline concentration-response curve (0.01 to 10 μmol/l) was used to check contractile responsiveness of the tissue and all responses were expressed as percentage of the response to 10 μmol/l noradrenaline. Noradrenaline caused a concentration-dependent increase in contractile force in both atrial and ventricular trabeculae. In contrast, though 5-HT (0.01 to 100 μmol/l) did increase force of contraction in atrial tissue (maximum: 72±20% of the response to noradrenaline 10 μmol/l), the contractility of ventricular trabeculae was not significantly affected (maximum: 12±6%). The present data show that, in contrast to atrial tissue, contractile force of ventricular tissue could not be significantly affected by 5-HT To our knowledge, this is the first study to show that an agent which increased force of contraction in the atrium, did not have a corresponding effect on the ventricle. These findings may have important implications for a better understanding of the physiology and pharmacology of cardiac contractility.